Photographing optical device

ABSTRACT

A photographing optical device may include a movable module including a movable body and a holding body; a support body to hold the movable module; a lens drive coil attached to the movable body; a shake correction coil attached to the support body, and a plurality of drive magnets attached to the holding body. The holding body may include a first magnet fixing member and a second magnet fixing member. The first magnet fixing member and the second magnet fixing member may be formed in a frame shape. The movable body may be disposed on inner peripheral sides of the first magnet fixing member and the second magnet fixing member. The support body may include a case body structuring an outer peripheral face of the support body. An object side end of the case body may include a facing part which faces an end face of the movable body.

CROSS REFERENCE TO PRIOR APPLICATIONS

The present application is a continuation application of U.S. patentapplication Ser. No. 14/648,484, filed on May 29, 2015, the entirecontents of which are incorporated herein by reference and priority towhich is hereby claimed. Application Ser. No. 14/648,484 is the U.S.National stage of application No. PCT/JP2013/072169, filed Aug. 20,2013. Priority under 35 U.S.C. § 119(a) and 35 U.S.C. § 365(b) is herebyclaimed from Japanese Application No. 2012-260756, filed Nov. 29, 2012,the disclosures of which are both also incorporated herein by reference.

FIELD OF THE INVENTION

The present invention relates to a photographing optical device having ashake correction function structured to swing a movable module on whicha lens and an imaging element are mounted to correct a shake.

BACKGROUND

Conventionally, a photographing optical device has been known which isprovided with a shake correction function structured to swing a movablemodule on which a lens and an imaging element are mounted to correct ashake (see, for example, Patent Literature 1). The photographing opticaldevice described in Patent Literature 1 includes a movable module onwhich a lens and an imaging element are mounted and a support body whichswingably supports the movable module.

In the photographing optical device, the movable module includes amovable body which holds a lens and is movable in an optical axisdirection of the lens, and a holding body which movably holds themovable body in the optical axis direction. The holding body is providedwith a cover member structuring a part of an outer peripheral face ofthe movable module. The cover member is formed in a substantiallybottomed rectangular tube shape having a bottom part and a tube part,and the bottom part is disposed on an object side with respect to themovable body. The bottom part of the cover member is capable of abuttingwith a part of an end face on an object side of the movable body. Thebottom part of the cover member functions to restrict a movable range ofthe movable body to an object side when an impact is applied to thephotographing optical device and prevents damage of a plate spring whichconnects the movable body with the holding body.

Further, in the photographing optical device, the support body isprovided with a case body structuring an outer peripheral face of thephotographing optical device. The case body is formed in a substantiallybottomed rectangular tube shape having a bottom part and a tube part andthe bottom part structures an end face on an anti-object side of thephotographing optical device. An end face on an object side of the casebody is disposed on an object side relative to the bottom part of thecover member.

PATENT LITERATURE

[PTL 1] Japanese Patent Laid-Open No. 2011-203476

In a market of a portable apparatus such as a cell phone on which thephotographing optical device described in Patent Literature 1 ismounted, a demand for making the apparatus thinner has been furtherincreased in recent years. Therefore, a demand for making thinner aphotographing optical device which is mounted on a portable apparatus isalso increased.

SUMMARY

In view of the problem described above, at least an embodiment of thepresent invention provides a photographing optical device which iscapable of being made thinner in comparison with the conventionaldevice.

To achieve the above, at least an embodiment of the present inventionprovides a photographing optical device including a movable modulehaving a movable body which holds a lens and is movable in an opticalaxis direction of the lens and a holding body structured to movably holdthe movable body in the optical axis direction, a support bodystructured to swingably hold the movable module, a lens drive coil whichis attached to the movable body, a shake correction coil which isattached to the support body, and a plurality of drive magnets having afirst opposed face which faces the lens drive coil and a second opposedface which faces the shake correction coil, the drive magnets beingattached to the holding body. When one side in the optical axisdirection is an object side and the other side in the optical axisdirection is an anti-object side, the holding body includes a firstmagnet fixing member to which end faces on the object side of theplurality of the drive magnets are fixed, and a second magnet fixingmember to which end faces on the anti-object side of the plurality ofthe drive magnets are fixed. The first magnet fixing member and thesecond magnet fixing member are formed in a frame shape, the movablebody is disposed on inner peripheral sides of the first magnet fixingmember and the second magnet fixing member formed in the frame shape,the support body includes a case body structuring an outer peripheralface of the support body, and an object side end of the case body isformed with a facing part which faces a part of an end face on theobject side of the movable body in the optical axis direction so as tobe capable of abutting with the part of the end face on the object sideof the movable body.

In the photographing optical device in accordance with at least anembodiment of the present invention, a support body which swingablyholds a movable module includes a case body structuring an outerperipheral face of the support body. Further, in at least an embodimentof the present invention, a facing part which faces a part of an endface on an object side of the movable body in an optical axis directionis formed in an object side end of the case body so as to be capable ofabutting with the part of the end face on the object side of the movablebody. Therefore, according to at least an embodiment of the presentinvention, even in a case that the bottom part of the cover memberincluded in the photographing optical device described in PatentLiterature 1 is not provided, when an impact is applied to thephotographing optical device, a movable range of the movable body on theobject side can be restricted by utilizing the facing part of the casebody. Accordingly, in at least an embodiment of the present invention,the size in the optical axis direction of the photographing opticaldevice can be reduced by an amount of the bottom part of the covermember which is provided in the conventional photographing opticaldevice. In other words, according to at least an embodiment of thepresent invention, the photographing optical device can be made furtherthinner in comparison with the conventional device.

Further, in at least an embodiment of the present invention, the lensdrive mechanism for driving the movable body in the optical axisdirection with respect to the holding body and the shake correctionmechanism for swinging the movable module with respect to the supportbody to correct a shake are structured by using common drive magnets.Therefore, the number of components can be reduced in comparison with acase that magnets for the lens drive mechanism and magnets for the shakecorrection mechanism are provided separately. Accordingly, in at leastan embodiment of the present invention, the size of the photographingoptical device can be also reduced in a radial direction which isperpendicular to the optical axis direction.

In at least an embodiment of the present invention, it is preferablethat the photographing optical device includes a first plate springwhich connects the movable module with the support body on theanti-object side, and the second magnet fixing member is formed so as toprotrude to an outer peripheral side relative to the drive magnets.According to this structure, when an impact is applied to thephotographing optical device, a swing range of the movable module in adirection perpendicular to the optical axis direction can be restrictedby using the second magnet fixing member to prevent damage of the firstplate spring. Therefore, in comparison with a case that, in addition tothe second magnet fixing member, another member is separately providedfor restricting a swing range of the movable module in a directionperpendicular to the optical axis direction, the structure of thephotographing optical device can be simplified.

In at least an embodiment of the present invention, it is preferablethat the photographing optical device includes second plate springsstructured to connect the movable body with the holding body on both endsides of the movable body in the optical axis direction, the firstmagnet fixing member and the second magnet fixing member are formed in asubstantially quadrangular frame shape when viewed in the optical axisdirection, an outer peripheral face of the movable body is formed in asubstantially octagonal shape when viewed in the optical axis direction,the second plate spring is provided with a movable body fixed part whichis fixed to the movable body, a holding body fixed part which is fixedto the first magnet fixing member or the second magnet fixing member,and spring parts which are disposed between four corner portions of thefirst magnet fixing member or the second magnet fixing member and themovable body and are structured to connect the movable body fixed partwith the holding body fixed part. According to this structure, thespring parts are disposed in spaces, which are normally dealt as deadspaces, between four corner portions of the first magnet fixing memberand the second magnet fixing member and the movable body and thus thesize of the photographing optical device can be reduced in a directionperpendicular to the optical axis direction. Alternatively, a diameterof the lens can be increased without increasing the size of thephotographing optical device.

In at least an embodiment of the present invention, for example, thefirst magnet fixing member is provided with four corner parts in asubstantially “L”-shape respectively structuring the four cornerportions of the first magnet fixing member whose shape when viewed inthe optical axis direction is a substantially quadrangular frame shapeand four straight side parts in a straight shape connecting the cornerparts, the holding body fixed part of the second plate spring connectingthe movable body with the holding body on the object side of the movablebody is fixed to a face on the anti-object side of the corner part, anda face on the object side of the corner part is disposed on theanti-object side relative to a face on the object side of the straightside part, and a face on the anti-object side of the corner part isdisposed on the anti-object side relative to a face on the anti-objectside of the straight side part. In this case, contacting of the cornerpart of the first magnet fixing member with the case body can beprevented when the movable module is swung. Further, in this case, anurging force of the movable body to an anti-object side can be increasedby the second plate spring which connects the movable body with theholding body on the object side of the movable body.

In at least an embodiment of the present invention, it is preferablethat the photographing optical device includes second plate springsstructured to connect the movable body with the holding body on both endsides of the movable body in the optical axis direction, the firstmagnet fixing member is formed in a substantially quadrangular frameshape when viewed in the optical axis direction, the second plate springwhich connects the movable body with the holding body on the object sideof the movable body is provided with a movable body fixed part which isfixed to the movable body, holding body fixed parts which are fixed tothe first magnet fixing member, and spring parts which connect themovable body fixed part with the holding body fixed parts, and theholding body fixed parts of the second plate spring which connect themovable body with the holding body on the object side of the movablebody are fixed to faces on the object side of four corner portions ofthe first magnet fixing member whose shape when viewed in the opticalaxis direction is a substantially quadrangular frame shape.

In the movable module structuring the photographing optical device, whenan electric current is not supplied to the lens drive coils, the movablebody is commonly urged to the anti-object side by the second platespring connecting the movable body with holding body on the object sideof the movable body for holding the movable body at a predeterminedreference position. Specifically, when the movable body is located at areference position, the movable body fixed part is fixed to the movablebody and the holding body fixed part is fixed to the first magnet fixingmember so that the movable body fixed part of the second plate spring isdisposed on the object side relative to the holding body fixed part.Therefore, when the holding body fixed part is fixed to faces on theanti-object side of four corner portions of the first magnet fixingmember, the spring parts of the second plate spring may be interferedwith the first magnet fixing member. On the other hand, in a case thatthe holding body fixed parts are fixed to faces on the object side offour corner portions of the first magnet fixing member, the spring partsand the first magnet fixing member can be prevented from beinginterfered with each other. Further, the holding body fixed parts of thesecond plate spring in a state that the movable body fixed part has beenfixed to the movable body can be easily fixed to a face on the objectside of the first magnet fixing member from the object side.

In at least an embodiment of the present invention, it is preferablethat the movable body includes a sleeve whose outer peripheral face iswound around and fixed with the lens drive coil and a stopper which isfixed on the object side of the sleeve, the stopper is formed so as toenlarge to an outer peripheral side relative to the outer peripheralface of the sleeve, and at least a part of the stopper faces the facingpart in the optical axis direction so as to be capable of abutting withthe facing part. A through-hole for exposing a lens is formed in anobject side end of the case body. Therefore, when the movable module isswung or, when the movable body is moved to an object side in a statethat the movable module is inclined with respect to the support body, anend face on the object side of the movable body may be projected fromthe case body to the object side without abutting of the end face on theobject side of the movable body with the facing part. However, accordingto this structure, when the movable module is swung or, when the movablebody is moved to an object side in a state that the movable module isinclined with respect to the support body, the stopper which is fixed tothe object side of the sleeve can be surely abutted with the facing partand thus the object side end of the movable body can be prevented fromprojecting from the case body to the object side.

In at least an embodiment of the present invention, it is preferablethat the stopper is formed in a ring shape whose outer peripheral end isformed in a circular shape. According to this structure, even when themovable module is inclined in any direction with respect to the supportbody, the stopper can be surely abutted with the facing part.

In at least an embodiment of the present invention, it is preferablethat the photographing optical device includes second plate springsstructured to connect the movable body with the holding body on both endsides of the movable body in the optical axis direction, the secondplate spring which connects the movable body with the holding body onthe object side of the movable body is provided with a movable bodyfixed part which is fixed to the movable body, holding body fixed partswhich are fixed to the first magnet fixing member, and spring partswhich connect the movable body fixed part with the holding body fixedparts, and the movable body fixed part of the second plate spring whichconnects the movable body with the holding body on the object side ofthe movable body is fixed in a sandwiched state between a spring fixingface formed on the object side of the sleeve and the stopper in theoptical axis direction. According to this structure, a fixed strength ofthe movable body fixed part can be increased.

In at least an embodiment of the present invention, for example, an endface on the object side of the case body where the facing part is formedis formed with a cut-out part for exposing a part of the first magnetfixing member when viewed in the optical axis direction. In this case,when the photographing optical device is to be assembled, aligning ofthe case body with the first magnet fixing member in the optical axisdirection can be performed by utilizing an end face on the object sideof the first magnet fixing member. In other words, at a time ofassembling of the photographing optical device, aligning of the casebody with the drive magnets in the optical axis direction can beperformed by utilizing the end face on the object side of the firstmagnet fixing member.

In at least an embodiment of the present invention, it is preferablethat surfaces of the drive magnet, the first magnet fixing member andthe second magnet fixing member are formed with a nickel plated layercontaining at least nickel, the first magnet fixing member and the drivemagnet are joined to each other through a first joining layer which ismade of tin based metal containing at least tin and is disposed betweenthe first magnet fixing member and the drive magnet, and the secondmagnet fixing member and the drive magnet are joined to each otherthrough a second joining layer which is made of tin based metalcontaining at least tin and is disposed between the second magnet fixingmember and the drive magnet. According to this structure, for example, atin plated layer which is formed so as to coat over a nickel platedlayer on the surface of the drive magnet before joined to the firstmagnet fixing member and the second magnet fixing member is melted andsolidified at the time of joining of the first magnet fixing member andthe second magnet fixing member to the drive magnet and thereby thefirst joining layer and the second joining layer are formed and, in thismanner, the first magnet fixing member and the second magnet fixingmember and the drive magnet can be joined to each other. Therefore,protruding of the first joining layer and the second joining layer frombetween the first magnet fixing member and the second magnet fixingmember and the drive magnet can be prevented.

As described above, according to at least an embodiment of the presentinvention, the photographing optical device can be made thinner incomparison with the conventional device.

BRIEF DESCRIPTION OF DRAWINGS

Embodiments will now be described, by way of example only, withreference to the accompanying drawings which are meant to be exemplary,not limiting, and wherein like elements are numbered alike in severalFigures, in which:

FIG. 1 is a perspective view showing a photographing optical device inaccordance with an embodiment of the present invention.

FIG. 2 is a plan view showing the photographing optical device in FIG.1.

FIG. 3 is a cross-sectional view showing the “E-E” cross section in FIG.2.

FIG. 4 is an exploded perspective view showing the photographing opticaldevice in FIG. 1.

FIG. 5 is an exploded perspective view showing a movable module in FIG.3.

FIG. 6 is a perspective view for explaining a movable module inaccordance with another embodiment of the present invention.

FIG. 7 is an exploded perspective view showing a plate spring, a sleeve,a magnet fixing member, a stopper and the like shown in FIG. 6.

DESCRIPTION OF EMBODIMENTS

Embodiments of the present invention will be described below withreference to the accompanying drawings.

(Entire Structure of Photographing Optical Device)

FIG. 1 is a perspective view showing a photographing optical device 1 inaccordance with an embodiment of the present invention. FIG. 2 is a planview showing the photographing optical device 1 in FIG. 1. FIG. 3 is across-sectional view showing the “E-E” cross section in FIG. 2. FIG. 4is an exploded perspective view showing the photographing optical device1 in FIG. 1. FIG. 5 is an exploded perspective view showing a movablemodule 4 in FIG. 3. In the following descriptions, as shown in FIG. 1,respective three directions perpendicular to each other are set to be an“X” direction, a “Y” direction and a “Z” direction, and the “X”direction is referred to as a right and left direction, the “Y”direction is referred to as a front and rear direction, and the “Z”direction is referred to as an upper and lower direction. Further, a“Z1” direction side is referred to as an “upper” side and a “Z2”direction side is referred to as a “lower” side in FIG. 1 and the like.

A photographing optical device 1 in this embodiment is a small and thincamera which is mounted on a portable apparatus such as a cell phone, adrive recorder, a monitor camera system or the like and is provided withan autofocus function and a shake correction function. The photographingoptical device 1 is formed in a substantially quadrangular prism shapeas a whole. In this embodiment, the photographing optical device 1 isformed in a substantially square shape when viewed in a direction of anoptical axis “L” (optical axis direction) of a lens for photographingand four side faces of the photographing optical device 1 aresubstantially parallel to planes formed of the right and left directionand the upper and lower direction (in other words, the “Z-X” planeformed of the “Z” direction and the “X” direction) or planes formed ofthe front and rear direction and the upper and lower direction (in otherwords, the “Y-Z” plane formed of the “Y” direction and the “Z”direction).

The photographing optical device 1 includes a movable module 4 on whicha lens for photographing and an imaging element are mounted and asupport body 5 which swingably holds the movable module 4. The movablemodule 4 is connected with the support body 5 through a plate spring 6which is a first plate spring. In this embodiment, the upper and lowerdirection is substantially coincided with an optical axis direction ofthe movable module 4 when the movable module 4 is not swung. Further, inthis embodiment, an imaging element is mounted on a lower end of themovable module 4 and an object to be photographed which is disposed onan upper side is photographed. In other words, in this embodiment, anupper side (“Z1” direction side) is an object to be photographed side(object side) which is one side in the optical axis direction and alower side (“Z2” direction side) is an anti-object side (imaging elementside, image side) which is the other side in the optical axis direction.

The movable module 4 is formed in a substantially quadrangular prismshape as a whole. In this embodiment, the movable module 4 is formed ina substantially square shape when viewed in the optical axis direction.This movable module 4 includes a movable body 8 which holds a lens andis movable in the optical axis direction and a holding body 9 whichmovably holds the movable body 8 in the optical axis direction. Themovable body 8 is movably held by the holding body 9 through a platespring 10 connecting the movable body 8 with the holding body 9 on anupper end side of the movable body 8 and a plate spring 11 connectingthe movable body 8 with the holding body 9 on a lower end side of themovable body 8. The plate springs 10 and 11 in this embodiment aresecond plate springs which respectively connect the movable body 8 withthe holding body 9 on both end sides of the movable body 8 in theoptical axis direction.

The movable body 8 includes a lens holder 12 to which a plurality oflenses are fixed and a sleeve 13 which holds the lens holder 12. Theholding body 9 includes a magnet fixing member 14 as a first magnetfixing member to which upper end faces (end faces on an object side) ofdrive magnets 38 described below are fixed, a magnet fixing member 15 asa second magnet fixing member to which lower end faces (end faces on ananti-object side) of the drive magnets 38 are fixed, and a base member16 which structures a lower end side portion of the movable module 4.

The lens holder 12 is formed in a substantially cylindrical tube shape.A plurality of lenses is fixed to an inner peripheral side of the lensholder 12. The sleeve 13 is formed of resin material. Further, thesleeve 13 is formed in a substantially tube shape. Specifically, thesleeve 13 is formed in a substantially tube shape whose inner peripheryof the sleeve 13 when viewed in the optical axis direction is formed ina circular shape and whose outer periphery of the sleeve 13 when viewedin the optical axis direction is formed in a substantially octagonalshape. In this embodiment, an outer peripheral face of the sleeve 13 isformed in a substantially regular octagonal shape when viewed in theoptical axis direction. The sleeve 13 holds the lens holder 12 on itsinner peripheral side. In other words, an outer peripheral face of thelens holder 12 is fixed to an inner peripheral face of the sleeve 13.

In this embodiment, an outer peripheral face of the sleeve 13 is anouter peripheral face of the movable body 8 and thus the outerperipheral face of the movable body 8 is formed in a substantiallyregular octagonal shape when viewed in the optical axis direction. Whenthe movable body 8 is viewed in the optical axis direction in a statethat the movable module 4 is not swung, two parallel sides of eightsides of the outer peripheral face of the movable body 8 formed in asubstantially octagonal shape are substantially parallel to the “Z-X”plane, and two sides which are perpendicular to the two parallel sidesand are parallel to each other are substantially parallel to the “Y-Z”plane, and remaining four sides are inclined at substantially 45° withrespect to the “Z-X” plane and the “Y-Z” plane.

The magnet fixing members 14 and 15 are, for example, formed of anonmagnetic stainless-steel plate. Surfaces of the magnet fixing members14 and 15 are formed with a nickel plated layer composed of nickel alloycontaining nickel as a main component or composed of nickel. Further,the magnet fixing members 14 and 15 are formed in a frame shape.Specifically, the magnet fixing members 14 and 15 are formed in asubstantially quadrangular frame shape when viewed in the optical axisdirection. More specifically, the magnet fixing members 14 and 15 areformed in a substantially square frame shape when viewed in the opticalaxis direction.

In this embodiment, an inner peripheral end of the magnet fixing member14 and an inner peripheral end of the magnet fixing member 15 aredisposed at substantially the same position as each other in the frontand rear direction and in the right and left direction. On the otherhand, an outer peripheral end of the magnet fixing member 15 is disposedon an outer peripheral side relative to an outer peripheral end of themagnet fixing member 14 in the front and rear direction and in the rightand left direction. In other words, an outward form of the magnet fixingmember 15 is larger than an outward form of the magnet fixing member 14.The movable body 8 is disposed on inner peripheral sides of the magnetfixing members 14 and 15 formed in a frame shape.

The magnet fixing member 14 is structured of four corner parts 14 a in asubstantially “L”-shape structuring respective four corner portions ofthe magnet fixing member 14 and four straight side parts 14 b in astraight shape which respectively connect two corner parts 14 a witheach other. Two of four straight side parts 14 b which are parallel toeach other are disposed so as to be substantially parallel to the rightand left direction and remaining two straight side parts 14 b which areparallel to each other are disposed so as to be substantially parallelto the front and rear direction. As shown in FIG. 5, an upper face ofthe corner part 14 a is disposed on a lower side relative to an upperface of the straight side part 14 b, and an under face of the cornerpart 14 a is disposed on a lower side relative to an under face of thestraight side part 14 b.

The magnet fixing member 15 is structured of four corner parts 15 a in asubstantially “L”-shape which respectively structure four cornerportions of the magnet fixing member 15 and four straight side parts 15b in a straight shape which connect two corner parts 15 a with eachother. Two of four straight side parts 15 b which are parallel to eachother are disposed so as to be substantially parallel to the right andleft direction and remaining two straight side parts 15 b which areparallel to each other are disposed so as to be substantially parallelto the front and rear direction. As shown in FIG. 5, an upper face ofthe corner part 15 a is disposed on the same plane as an upper face ofthe straight side part 15 b and an under face of the corner part 15 a isdisposed on the same plane as an under face of the straight side part 15b.

The base member 16 is formed in a flat and substantially rectangularprism shape. A center of the base member 16 is formed with athrough-hole 16 a and the base member 16 is formed in a substantiallysquare frame shape when viewed in the optical axis direction. An upperend face of the base member 16 is fixed to the under face of the magnetfixing member 15. An IR cut filter 17 is fixed to the through-hole 16 a.

The plate spring 10 is provided with a movable body fixed part 10 awhich is fixed to an upper end side of the sleeve 13 of the movable body8, four holding body fixed parts 10 b which are fixed to the magnetfixing member 14, and spring parts 10 c connecting the movable bodyfixed part 10 a with the holding body fixed parts 10 b. The plate spring10 is fixed to the sleeve 13 and the magnet fixing member 14 so that itsthickness direction and the upper and lower direction are substantiallycoincided with each other.

The movable body fixed part 10 a is formed in a frame shape whose innerperiphery is formed in a circular shape and whose outer periphery isformed in a substantially octagonal shape. The holding body fixed part10 b is formed in a substantially pentagonal shape. The spring part 10 cis formed in a meandered line shape so that a desired springcharacteristic is obtained. Four holding body fixed parts 10 b aredisposed on an outer peripheral side with respect to the movable bodyfixed part 10 a. Further, each of four holding body fixed parts 10 b isfixed to each of the under faces (face on an anti-object side) of fourcorner parts 14 a of the magnet fixing member 14. The spring part 10 cis disposed between the corner part 14 a of the magnet fixing member 14and the movable body fixed part 10 a. In other words, the spring parts10 c are disposed between four corner portions of the magnet fixingmember 14 and the movable body 8.

The plate spring 11 is structured of two spring pieces 19. The springpiece 19 is provided with a movable body fixed part 19 a which is fixedto a lower end side of the sleeve 13 of the movable body 8, two holdingbody fixed parts 19 b which are fixed to the magnet fixing member 15,and spring parts 19 c connecting the movable body fixed part 19 a withthe holding body fixed parts 19 b. The plate spring 11 is fixed to thesleeve 13 and the magnet fixing member 15 so that its thicknessdirection and the upper and lower direction are substantially coincidedwith each other.

The movable body fixed part 19 a is formed in a substantiallysemicircular shape. The holding body fixed part 19 b is formed in asubstantially quadrangular shape. The spring part 19 c is formed in ameandered line shape so that a desired spring characteristic isobtained. Two holding body fixed parts 19 b of one of two spring pieces19 and two holding body fixed parts 19 b of the other spring piece 19are respectively disposed on outer peripheral sides of the movable bodyfixed parts 19 a. Further, two holding body fixed parts 19 b of one ofthe spring pieces 19 and two holding body fixed parts 19 b of the otherspring piece 19 are respectively fixed to upper faces (face on an objectside) of four corner parts 15 a of the magnet fixing member 15. Thespring part 19 c is disposed between the corner part 15 a of the magnetfixing member 15 and the movable body fixed part 19 b. In other words,the spring parts 19 c are disposed between four corner portions of themagnet fixing member 15 and the movable body 8.

In this embodiment, the plate spring 10 is fixed to the sleeve 13 andthe magnet fixing member 14 in a resiliently bent state so as to urgethe movable body 8 to a lower direction when the movable body 8 islocated at a predetermined reference position where the lower end of themovable body 8 and the upper end face of the base member 16 are abuttedwith each other. In other words, the movable body fixed part 10 a isfixed to the upper end side of the sleeve 13 and the holding body fixedparts 10 b are fixed to the under faces of the corner parts 14 a of themagnet fixing member 14 so that the movable body fixed part 10 a isdisposed on an upper side relative to the holding body fixed parts 10 bwhen the movable body 8 is located at a reference position. Further,when the movable body 8 is located at a predetermined referenceposition, the plate spring 11 is fixed to the sleeve 13 and the magnetfixing member 15 so as not to apply an urging force or so as to urge themovable body 8 in the lower direction similarly to the plate spring 10.

An imaging element is mounted on a circuit board 20. The circuit board20 is fixed to an under face of the base member 16. An FPC (flexibleprinted circuit board) 21 is connected with the circuit board 20. TheFPC 21 is led around on a lower end side of the photographing opticaldevice 1 and is extended out from a side face of the photographingoptical device 1. An abutting plate 22 with which a support point member27 described below is abutted is fixed to an under face of the circuitboard 20.

The support body 5 includes a case body 25 which structures four sidefaces of the support body 5 in the front and rear direction and theright and left direction and a lower case body 26 which structures alower end side portion of the support body 5. In this embodiment, thecase body 25 structures four side faces of the photographing opticaldevice 1 in the front and rear direction and the right and leftdirection and the lower case body 26 structures a lower end side portionof the photographing optical device 1.

The case body 25 is, for example, formed of nonmagnetic metal material.Further, the case body 25 is formed in a substantially bottomedrectangular tube shape which is provided with a bottom part 25 a formedin a substantially quadrangular flat plate shape and a tube part 25 bformed in a substantially rectangular tube shape. The bottom part 25 ain this embodiment is formed in a substantially square flat plate shape.Further, the bottom part 25 a is connected with an upper end of the tubepart 25 b and structures an upper end face (in other words, an end faceon an object side) of the case body 25. The case body 25 is disposed sothat its axial direction and the upper and lower direction aresubstantially coincided with each other. Further, the case body 25 isdisposed so as to cover the movable module 4 and a lens drive mechanism30 and a shake correction mechanism 31 described below from an outerperipheral side. A specific structure of the case body 25 will bedescribed below.

The lower case body 26 is, as shown in FIG. 4, structured of a bottompart 26 a which is formed in a substantially square flat plate shape andthree side face parts 26 b which are respectively stood up to an upperside from three sides of the bottom part 26 a. The bottom part 26 a ofthe lower case body 26 structures an under face of the photographingoptical device 1. A support point member 27 is fixed to a center of thebottom part 26 a. The support point member 27 is formed with asupporting point part 27 a which is protruded to an upper side andserves as a supporting point for swinging of the movable module 4. Thesurface of the supporting point part 27 a is formed in a curved shape inwhich a part of a spherical face is cut off. The supporting point part27 a is abutted with the abutting plate 22.

The plate spring 6 is provided with a movable side fixed part which isfixed to the movable module 4, a support side fixed part which is fixedto the support body 5, and four arm parts connecting the movable sidefixed part with the support side fixed part. The movable side fixed partis fixed to a lower end side of the movable module 4 and the supportside fixed part is fixed to an upper end of the side face part 26 b ofthe lower case body 26 and thus the plate spring 6 connects the movablemodule 4 with the support body 5 on a lower end side (in other words,anti-object side). In this embodiment, the arm parts are resilientlybent with respect to the support side fixed part and thereby swingoperation of the movable module 4 which is fixed to the movable sidefixed part can be performed. The plate spring 6 is fixed in aresiliently bent state so as to generate pressurization for surelyabutting the supporting point part 27 a with the abutting plate 22 (inother words, so that an urging force for urging the movable module 4 inthe lower direction is generated).

Further, the photographing optical device 1 includes a lens drivemechanism 30 for driving the movable body 8 in the optical axisdirection with respect to the holding body 9 and a shake correctionmechanism 31 for correcting a shake such as a hand shake by swinging themovable module 4 with respect to the support body 5. Structures of thelens drive mechanism 30 and the shake correction mechanism 31 will bedescribed below.

(Structures of Lens Drive Mechanism and Shake Correction Mechanism)

An outer peripheral face of the sleeve 13 is attached with two lensdrive coils 32 structuring the lens drive mechanism 30. The lens drivecoil 32 is wound around along the outer peripheral face of the sleeve13. Two lens drive coils 32 are wound around so that their windingdirections are different from each other. Further, two lens drive coils32 are fixed to the outer peripheral face of the sleeve 13 with apredetermined space therebetween in the upper and lower direction.

Sheet-shaped coils 34 each of which is integrally provided with a coilpart 33 as a shake correction coil structuring the shake correctionmechanism 31 are respectively disposed on inner sides of four side facesstructuring the tube part 25 b of the case body 25. In other words, foursheet-shaped coils 34 are disposed on an inner peripheral side of thetube part 25 b. The sheet-shaped coil 34 is a flexible printed coil (FPcoil) which is structured so that the coil part 33 made of minute copperwiring is formed on a printed circuit board. The coil part 33 is formedin a substantially rectangular frame shape and is disposed so that itslong side portions are overlapped with each other in the upper and lowerdirection. Further, a surface of the coil part 33 is covered with aninsulation film.

Four sheet-shaped coils 34 are electrically connected with an FPC 35 forrelaying. The FPC 35 is disposed on an inner peripheral side of the tubepart 25 b in a bent state in a substantially rectangular tube shape. Thefour sheet-shaped coils 34 are fixed to an inner peripheral face of theFPC 35 which is bent in a substantially rectangular tube shape and anouter peripheral face of the FPC 35 is fixed to an inner peripheral faceof the tube part 25 b. In other words, four sheet-shaped coils 34 arefixed to the inner peripheral face of the tube part 25 b through the FPC35. The FPC 35 is connected with an FPC 21. A photo reflector 36 fordetecting a position of the movable module 4 with respect to the supportbody 5 is mounted on one of two sheet-shaped coils 34 which are disposedsubstantially parallel to the “Z-X” plane and one of two sheet-shapedcoils 34 which are disposed parallel to the “Y-Z” plane.

A drive magnet 38 which is formed in a substantially rectangular flatplate shape is fixed to each of four straight side parts 14 b of themagnet fixing member 14 and each of four straight side parts 15 b of themagnet fixing member 15. In four drive magnets 38 which are fixed to themagnet fixing members 14 and 15, two drive magnets 38 disposed parallelto each other are disposed substantially parallel to the “Z-X” plane andremaining two drive magnets 38 disposed parallel to each other aredisposed substantially parallel to the “Y-Z” plane.

The drive magnet 38 is a neodymium magnet containing neodymium, iron andboron as main components. The drive magnet 38 is structured of twomagnet pieces, i.e., a first magnet piece 38 a and a second magnet piece38 b which are formed in a substantially rectangular flat plate shape,and a magnetic member 38 c which is disposed between the first magnetpiece 38 a and the second magnet piece 38 b. Specifically, the firstmagnet piece 38 a, the second magnet piece 38 b and the magnetic member38 c are adhesively bonded and fixed to each other in a state that themagnetic member 38 c is sandwiched between an under face of the firstmagnet piece 38 a and an upper face of the second magnet piece 38 b andthereby the drive magnet 38 is formed. A surface of the drive magnet 38is formed with a nickel plated layer composed of nickel alloy containingnickel as a main component or composed of nickel.

The drive magnet 38 is magnetized so that a magnetic pole formed on oneside face and a magnetic pole formed on the other side face aredifferent from each other. In other words, the drive magnet 38 disposedsubstantially parallel to the “Z-X” plane is magnetized so that amagnetic pole formed on a front side face of the drive magnet 38 and amagnetic pole formed on its rear side face are different from eachother. Further, the drive magnet 38 disposed substantially parallel tothe “Y-Z” plane is magnetized so that a magnetic pole formed on a rightside face of the drive magnet 38 and a magnetic pole formed on its leftside face are different from each other.

The side face of the drive magnet 38 is magnetized so that two differentmagnetic poles are overlapped with each other in the upper and lowerdirection. Specifically, the drive magnet 38 disposed substantiallyparallel to the “Z-X” plane is magnetized so that a magnetic pole formedon an outer side face of the first magnet piece 38 a and a magnetic poleformed on an outer side face of the second magnet piece 38 b in thefront and rear direction are different from each other (in other words,a magnetic pole formed on an inner side face of the first magnet piece38 a and a magnetic pole formed on an inner side face of the secondmagnet piece 38 b in the front and rear direction are different fromeach other). Further, the drive magnet 38 disposed substantiallyparallel to the “Y-Z” plane is magnetized so that a magnetic pole formedon an outer side face of the first magnet piece 38 a and a magnetic poleformed on an outer side face of the second magnet piece 38 b in theright and left direction are different from each other (in other words,a magnetic pole formed on an inner side face of the first magnet piece38 a and a magnetic pole formed on an inner side face of the secondmagnet piece 38 b in the right and left direction are different fromeach other).

In this embodiment, four drive magnets 38 are disposed so that allmagnetic poles on inner side faces of four first magnet pieces 38 a arethe same magnetic poles as each other (in other words, all magneticpoles on inner side faces of four second magnet pieces 38 b are the samemagnetic poles as each other). In other words, in this embodiment, fourdrive magnets 38 are disposed so that all magnetic poles on outer sidefaces of four first magnet pieces 38 a are the same magnetic poles aseach other (in other words, all magnetic poles on outer side faces offour second magnet pieces 38 b are the same magnetic poles as eachother).

Inner side faces of the first magnet pieces 38 a in the front and reardirection or the right and left direction face an outer peripheral faceof one of two lens drive coils 32 through a predetermined gap space, andinner side faces of the second magnet pieces 38 b in the front and reardirection or the right and left direction face an outer peripheral faceof the other lens drive coil 32 through a predetermined gap space.Further, outer side faces of the first magnet pieces 38 a in the frontand rear direction or the right and left direction face one of two longside portions of the coil part 33 through a predetermined gap space, andouter side faces of the second magnet pieces 38 b in the front and reardirection or the right and left direction face the other of two longside portions of the coil part 33 through a predetermined gap space.

In this embodiment, the lens drive mechanism 30 is structured of thelens drive coils 32 and the drive magnets 38 and, when an electriccurrent is supplied to the lens drive coils 32, the lens is moved in theoptical axis direction together with the movable body 8. Further, inthis embodiment, the shake correction mechanism 31 is structured of thecoil parts 33 and the drive magnets 38 and, when a variation ofinclination of the photographing optical device 1 is detected by agyroscope disposed on an outer side of the photographing optical device1, an electric current is supplied to the coil parts 33 based on adetected result by the gyroscope. Further, when an electric current issupplied to the coil parts 33, the movable module 4 is swung so as toincline the optical axis “L” with the supporting point part 27 a as aswing center to correct the shake.

The magnet fixing members 14 and 15 are fixed with a reflecting plate 39for reflecting light from a light emitting element of the photoreflector 36 to a light receiving element of the photo reflector 36.Further, in this embodiment, the inner side faces of the drive magnets38 in the front and rear direction or the right and left direction arefirst opposed faces facing the lens drive coil 32, and the outer sidefaces of the drive magnets 38 in the front and rear direction or theright and left direction are second opposed faces facing the coil parts33 which are the shake correction coils.

As described above, the drive magnets 38 are fixed to the magnet fixingmembers 14 and 15. In this embodiment, the drive magnet 38 and themagnet fixing member 14 are joined to each other by a first joininglayer comprised of tin based metal containing at least tin. Similarly,the drive magnet 38 and the magnet fixing member 15 are joined to eachother by a second joining layer comprised of tin based metal containingat least tin. The first joining layer and the second joining layer arestructured of tin, tin alloy containing copper, tin alloy containinggold, tin alloy containing silver, tin alloy containing bismuth, or thelike.

A surface of the drive magnet 38 before fixed to the magnet fixingmembers 14 and 15 is formed with a tin plated layer, which becomes thefirst joining layer and the second joining layer after being joined, soas to cover the nickel plated layer. In order to fix the drive magnets38 to the magnet fixing members 14 and 15, in a state that four drivemagnets 38 are sandwiched between the magnet fixing member 14 and themagnet fixing member 15, while pressurized so that the magnet fixingmember 14 and the drive magnets 38 are firmly contacted and the magnetfixing member 15 and the drive magnets 38 are firmly contacted, themagnet fixing members 14 and 15 and the drive magnets 38 are heated andthen cooled. When the magnet fixing members 14 and 15 and the drivemagnets 38 are heated, the tin plated layer on the surface of the drivemagnet 38 is melted and then, when the magnet fixing members 14 and 15and the drive magnets 38 are cooled, the melted tin based metal issolidified to form the first joining layer and the second joining layerand, as a result, the drive magnets 38 are fixed to the magnet fixingmembers 14 and 15.

Further, as shown in FIG. 3, the drive magnets 38 are fixed to themagnet fixing members 14 and 15 so that the inner side faces of thedrive magnets 38 in the front and rear direction or the right and leftdirection are substantially coincided with the inner peripheral ends ofthe magnet fixing members 14 and 15 in the front and rear direction orthe right and left direction. As described above, the outer peripheralend of the magnet fixing member 15 is disposed on an outer peripheralside relative to the outer peripheral end of the magnet fixing member 14in the front and rear direction and the right and left direction.Further, in this embodiment, the outer peripheral end of the magnetfixing member 15 is protruded to an outer peripheral side relative tothe outer side faces of the drive magnets 38 in the front and reardirection or the right and left direction. The magnet fixing member 15in this embodiment functions as a stopper for restricting a swing rangeof the movable module 4 in the front and rear direction and the rightand left direction when an impact is applied to the photographingoptical device 1. In this embodiment, the outer peripheral end of themagnet fixing member 14 is disposed on an inner peripheral side relativeto the outer side faces of the drive magnets 38 in the front and reardirection or the right and left direction.

(Structure of Case Body)

As described above, the case body 25 is provided with the bottom part 25a structuring an upper end face of the case body 25. The bottom part 25a is formed with a through-hole 25 c penetrating through in the upperand lower direction. The through-hole 25 c is formed so that its centerand the optical axis “L” are substantially coincided with each other. Afacing part 25 d which is protruded toward an inner side in the radialdirection of the lens is formed at an edge of the through-hole 25 c. Thefacing part 25 d is formed at four positions of the edge of thethrough-hole 25 c at a substantially 90° pitch with the optical axis “L”as a center. In other words, four facing parts 25 d are formed at theedge of the through-hole 25 c with a predetermined space therebetween ina circumferential direction of the lens. A cut-out part 25 e is formedbetween adjacent facing parts 25 d in the circumferential direction ofthe lens.

An inner peripheral end of the facing part 25 d is formed in asubstantially ¼ circular arc shape with the optical axis “L” as acenter. An inner peripheral end of the facing part 25 d is disposed onan inner peripheral side relative to an outer peripheral face of thesleeve 13 (in other words, an outer peripheral face of the movable body8) as shown in FIG. 2 and the facing part 25 d is capable of abuttingwith a part of an upper end of the sleeve 13 (in other words, an endface on an object side of the movable body 8). In other words, thefacing part 25 d faces a part of the end face on the object side of themovable body 8 so as to be capable of abutting with a part of the endface on the object side of the movable body 8. A gap space in theoptical axis direction between the end face on the object side of themovable body 8 and the facing part 25 d is set so that the movable body8 and the facing part 25 d are not contacted with each other even whenthe movable module 4 is swung in a state that the movable body 8 hasbeen moved to the upper limit during normal use of the photographingoptical device 1.

The cut-out part 25 e is formed in a substantially rectangular shapewhen viewed in the optical axis direction. An outer peripheral end ofthe cut-out part 25 e is, as shown in FIG. 2, disposed on an outerperipheral side relative to an inner peripheral end of the magnet fixingmember 14 and, when viewed in the optical axis direction, a part of themagnet fixing member 14 is exposed.

(Principal Effects in this Embodiment)

As described above, in this embodiment, the facing part 25 d formed inthe bottom part 25 a of the case body 25 faces a part of an end face onthe object side of the movable body 8 so as to be capable of abuttingwith the part of the end face on the object side of the movable body 8.Therefore, according to this embodiment, even when the bottom part ofthe cover member included in the photographing optical device describedin Patent Literature 1 is not provided, a movable range on an objectside of the movable body 8 can be restricted by utilizing the facingpart 25 d when an impact is applied to the photographing optical device1. Accordingly, in this embodiment, the size in the optical axisdirection of the photographing optical device 1 can be reduced by anamount of the bottom part of the cover member which is included in theconventional photographing optical device. In other words, according tothis embodiment, the photographing optical device 1 can be made thinnerthan the conventional device.

In this embodiment, a swing range of the movable module 4 is alsorestricted by setting the facing part 25 d to be abutted with the endface on the object side of the movable body 8 or the face on the objectside of the magnet fixing member 14. In other words, the facing part 25d in this embodiment also functions for restricting a swing range of themovable module 4.

In this embodiment, the lens drive mechanism 30 for driving the movablebody 8 in the optical axis direction with respect to the holding body 9and the shake correction mechanism 31 for swinging the movable module 4with respect to the support body 5 to correct a shake such as a handshake are structured by using the common drive magnets 38. Therefore,according to this embodiment, the number of components can be reduced incomparison with a case that magnets for the lens drive mechanism 30 andmagnets for the shake correction mechanism 31 are provided separately.Accordingly, in this embodiment, the size of the photographing opticaldevice 1 can be reduced in the front and rear direction and the rightand left direction.

In this embodiment, an outer peripheral end of the magnet fixing member15 is protruded to an outer peripheral side relative to the outer sidefaces of the drive magnets 38 in the front and rear direction or theright and left direction and thus the magnet fixing member 15 functionsas a stopper for restricting a swing range of the movable module 4 inthe front and rear direction and in the right and left direction when animpact is applied to the photographing optical device 1. Therefore,according to this embodiment, without separately providing a stopper forrestricting a swing range of the movable module 4 in the front and reardirection and the right and left direction, the swing range of themovable module 4 can be restricted to prevent damage of the plate spring6. Accordingly, in this embodiment, while the structure of thephotographing optical device 1 is simplified, damage of the plate spring6 can be prevented.

In this embodiment, the movable body 8 whose outer peripheral face whenviewed in the optical axis direction is formed in a substantiallyregular octagonal shape is disposed on inner peripheral sides of themagnet fixing members 14 and 15 whose shapes when viewed in the opticalaxis direction are substantially square frame shapes. Further, in thisembodiment, the spring parts 10 c of the plate spring 10 are disposedbetween the corner parts 14 a of the magnet fixing member 14 and themovable body 8, and the spring parts 19 c of the spring pieces 19 aredisposed between the corner parts 15 a of the magnet fixing member 15and the movable body 8. In other words, in this embodiment, the springparts 10 c and 19 c are disposed in spaces, which are easily dealt asdead spaces, between four corner portions of the magnet fixing members14 and 15 and the movable body 8. Therefore, according to thisembodiment, the size of the photographing optical device 1 can bereduced in the front and rear direction and the right and leftdirection. Alternatively, a diameter of the lens can be increasedwithout increasing the size of the photographing optical device 1.

In this embodiment, an upper face of the corner part 14 a of the magnetfixing member 14 is disposed on a lower side relative to an upper faceof the straight side part 14 b. Therefore, according to this embodiment,contacting of the corner part 14 a of the magnet fixing member 14 withthe case body 25 can be prevented when the movable module 4 is swung.Further, in this embodiment, an under face of the corner part 14 a ofthe magnet fixing member 14 to which the holding body fixed part 10 b ofthe plate spring 10 is fixed is disposed on a lower side relative to theupper face of the straight side part 14 b. Therefore, according to thisembodiment, an urging force of the movable body 8 to an anti-object sideby the plate spring 10 can be increased.

In this embodiment, the cut-out part 25 e is formed in the bottom part25 a of the case body 25 and, when viewed in the optical axis direction,a part of the magnet fixing member 14 is exposed. Therefore, accordingto this embodiment, when the photographing optical device 1 is to beassembled, aligning of the case body 25 with the magnet fixing member 14in the optical axis direction can be performed by utilizing an end faceon an object side of the magnet fixing member 14. In other words, inthis embodiment, at a time of assembling of the photographing opticaldevice 1, aligning of the case body 25 with the drive magnets 38 in theoptical axis direction can be performed by utilizing the end face on anobject side of the magnet fixing member 14. Further, in a case that themovable module 4 in an assembled state is attached to the case body 25,at a time of assembling of the photographing optical device 1, aligningof the movable module 4 with the magnet fixing member 14 in the opticalaxis direction can be performed by utilizing an end face on the objectside of the magnet fixing member 14.

In this embodiment, the magnet fixing members 14 and 15 and the drivemagnets 38 are joined to each other through the first joining layer andthe second joining layer, which are formed so that tin plated layers onthe surfaces of the drive magnets 38 before fixed to the magnet fixingmembers 14 and 15 are melted and solidified. Therefore, according tothis embodiment, protruding of the first joining layer and the secondjoining layer can be prevented between the magnet fixing member 14 andthe drive magnets 38 and between the magnet fixing member 15 and thedrive magnets 38.

(Modified Embodiment of Movable Module)

FIG. 6 is a perspective view for explaining a movable module 4 inaccordance with another embodiment of the present invention. FIG. 7 isan exploded perspective view showing a plate spring 10, a sleeve 13, amagnet fixing member 54, a stopper 55 and the like shown in FIG. 6. InFIGS. 6 and 7, the same structure as the embodiment described above isshown by using the same reference sign.

In the embodiment described above, the facing part 25 d of the bottompart 25 a structuring an upper end face of the case body 25 faces a partof an upper end of the sleeve 13 so as to be capable of abutting withthe part of the upper end of the sleeve 13. However, the presentinvention is not limited to this embodiment. For example, the facingpart 25 d may be faced with a part of an upper face of a stopper 55which is fixed to an upper end side of the sleeve 13 so as to be capableof abutting with the part of the upper face of the stopper 55 (see FIG.6).

The stopper 55 is formed of metal material. Further, the stopper 55 isformed in a flat plate shape. In addition, the stopper 55 is formed in aring shape whose outer peripheral end is formed in a circular shape.Specifically, the stopper 55 is formed in a circular ring shape whoseinner peripheral end is also formed in a circular shape. An outerdiameter of the stopper 55 is larger than an outer diameter of thesleeve 13 and the stopper 55 fixed to the upper end side of the sleeve13 is enlarged to an outer peripheral side relative to the outerperipheral face of the sleeve 13. A gap space in the optical axisdirection between the end face on an object side of the stopper 55 andthe facing part 25 d is set so that the stopper 55 and the facing part25 d are not contacted with each other even when the movable module 4 isswung in a state that the movable body 8 has been moved to the upperlimit during normal use of the photographing optical device 1.

Also in this modified embodiment, when an impact is applied to thephotographing optical device 1, a movable range on an object side of themovable body 8 can be restricted by utilizing the facing part 25 d andthe stopper 55. Therefore, similarly to the embodiment described above,the photographing optical device 1 can be made thinner than theconventional device.

In this embodiment, the bottom part 25 a of the case body 25 is formedwith the through-hole 25 c for exposing a lens. Further, in thephotographing optical device 1 in this embodiment, the lens holder 12 towhich a lens is fixed is inserted and attached to an inner peripheralside of the sleeve 13 from an upper side in the final stage ofassembling processes and thus the through-hole 25 c is formed relativelylarge. Therefore, when the movable module 4 is swung or, when themovable body 8 is moved to an object side in a state that the movablemodule 4 is inclined with respect to the support body 5, the upper endof the movable body 8 may be projected from the case body 25 to an upperside without the upper end face of the movable body 8 being abutted withthe facing part 25 d.

In this modified embodiment, the movable body 8 is provided with thestopper 55 which is fixed to an upper end side of the sleeve 13, and thestopper 55 is enlarged to an outer peripheral side relative to an outerperipheral face of the sleeve 13. Therefore, when the movable module 4is swung or, when the movable body 8 is moved to an object side in astate that the movable module 4 is inclined with respect to the supportbody 5, the stopper 55 structuring a part of an upper end face of themovable body 8 can be surely abutted with the facing part 25 d.Especially, in this modified embodiment, the stopper 55 is formed in aring shape whose outer peripheral end is formed in a circular shape andthus, even when the movable module 4 is inclined in any direction withrespect to the support body 5, the stopper 55 can be surely abutted withthe facing part 25 d. Therefore, the upper end of the movable body 8 canbe prevented from projecting out to an upper side from the case body 25.

Further, in the modified embodiment shown in FIGS. 6 and 7, thephotographing optical device 1 includes a magnet fixing member 54 as thefirst magnet fixing member instead of the magnet fixing member 14. Themagnet fixing member 54 is, similarly to the magnet fixing member 14,for example, formed of a nonmagnetic stainless-steel plate. Further, themagnet fixing member 54 is formed in a flat plate shape. In addition,the magnet fixing member 54 is formed in a substantially quadrangularframe shape when viewed in the optical axis direction. Specifically, themagnet fixing member 54 is formed in a frame shape whose innerperipheral end is formed in a substantially octagonal shape when viewedin the optical axis direction and whose outer peripheral end is formedin a substantially square shape when viewed in the optical axisdirection. In other words, the magnet fixing member 54 is structured offour substantially triangular-shaped corner parts 54 a which arerespectively disposed at four corner portions of the magnet fixingmember 54 and four straight side parts 54 b in a straight shape whichare disposed in parallel to the front and rear direction or the rightand left direction to connect the corner parts 54 a with each other.

The movable body fixed part 10 a of the plate spring 10 is fixed to aspring fixing face 13 a in a sandwiched state between the spring fixingface 13 a (see FIG. 7) formed on an upper end side of the sleeve 13 andan under face of the stopper 55. The spring fixing face 13 a is formedin a flat face shape perpendicular to the upper and lower direction andis formed in a circular ring shape. Further, each of four holding bodyfixed parts 10 b is fixed to an upper face of each of the corner parts54 a which are disposed at four corner portions of the magnet fixingmember 54.

As described above, the movable body fixed part 10 a is fixed to themovable body 8 and the holding body fixed part 10 b is fixed to theholding body 9 so that, when the movable body 8 is located at areference position, the movable body fixed part 10 a is disposed on anupper side relative to the holding body fixed part 10 b. Therefore, in acase that the holding body fixed part 10 b is fixed to an under face ofthe magnet fixing member 54 (or the magnet fixing member 14), the springpart 10 c may be interfered with the magnet fixing member 54 (or themagnet fixing member 14). However, according to this modifiedembodiment, the holding body fixed part 10 b is fixed to an upper faceof the magnet fixing member 54 and thus the spring part 10 c isprevented from being interfered with the magnet fixing member 54.Further, in a state that the movable body fixed part 10 a is fixed tothe sleeve 13, the holding body fixed part 10 b of the plate spring 10can be easily fixed to an upper face of the magnet fixing member 54 froman upper side and thus assembling of the photographing optical device 1is easily performed. Further, in this modified embodiment, the movablebody fixed part 10 a of the plate spring 10 is fixed in a sandwichedstate between the spring fixing face 13 a and the under face of thestopper 55 and thus a fixed strength of the movable body fixed part 10 acan be increased.

In this modified embodiment, the sleeve 13 and the stopper 55 areseparately formed from each other and thus, even when the sleeve 13 isformed of resin material, the stopper 55 can be formed of metalmaterial. Therefore, strength of the stopper 55 for restricting amovable range on an object side of the movable body 8 can be increased.Further, when the stopper 55 which is enlarged to an outer peripheralside relative to an outer peripheral face of the sleeve 13 is integrallyformed with the sleeve 13, attaching of the movable body fixed part 10 ato the movable body 8 may be difficult. However, in this modifiedembodiment, the sleeve 13 and the stopper 55 are separately formed fromeach other and thus, the stopper 55 can be attached after the movablebody fixed part 10 a has been fixed to the spring fixing face 13 a ofthe sleeve 13 and, therefore, the movable body fixed part 10 a can beeasily attached to the movable body 8.

In this modified embodiment, the movable body fixed part 10 a of theplate spring 10 is sandwiched between the spring fixing face 13 a of thesleeve 13 and the stopper 55, and the stopper 55 is fixed to the sleeve13 through the movable body fixed part 10 a. However, the stopper 55 maybe directly fixed to the sleeve 13. Further, in this modifiedembodiment, the shape of an inner peripheral end of the stopper 55 is acircular shape but the shape of the inner peripheral end of the stopper55 may be a polygonal shape.

Other Embodiments

Although the present invention has been shown and described withreference to a specific embodiment, various changes and modificationswill be apparent to those skilled in the art from the teachings herein.

In the embodiment described above, the case body 25 is formed in asubstantially bottomed rectangular tube shape and the bottom part 25 aand the tube part 25 b are integrally formed with each other. However,the present invention is not limited to this embodiment. For example,the bottom part 25 a and the tube part 25 b which are separately formedmay be fixed to each other.

In the embodiment described above, the magnet fixing members 14 and 15are formed in a substantially square frame shape when viewed in theoptical axis direction. However, the present invention is not limited tothis embodiment. For example, the magnet fixing members 14 and 15 may beformed in a quadrangular frame shape other than a substantially squareshape or may be formed in a polygonal frame shape other than aquadrangular shape. Further, the magnet fixing members 14 and 15 may beformed in a circular frame shape or in an elliptic frame shape.

In the embodiment described above, the magnet fixing member 15 functionsas a stopper for restricting a swing range of the movable module 4 inthe front and rear direction and the right and left direction. However,the present invention is not limited to this embodiment. For example, astopper for restricting a swing range of the movable module 4 may beseparately provided. In this case, for example, an outer peripheral endof the magnet fixing member 14 and an outer peripheral end of the magnetfixing member 15 are disposed at substantially the same position as eachother in the front and rear direction and the right and left direction.

In the embodiment described above, the cut-out part 25 e is formed inthe bottom part 25 a of the case body 25. However, no cut-out part 25 emay be formed in the bottom part 25 a of the case body 25. In this case,the bottom part 25 a is formed with one facing part 25 d in a ringshape. Further, in the embodiment described above, the magnet fixingmembers 14 and 15 and the drive magnets 38 are fixed to each other bythe first joining layer and the second joining layer made of tin basedmetal. However, the magnet fixing members 14 and 15 and the drive magnet38 may be fixed to each other by adhesion, soldering or the like.

In the embodiment described above, the drive magnet 38 is structured ofthe first magnet piece 38 a, the second magnet piece 38 b and themagnetic member 38 c. However, the drive magnet 38 may be structured ofthe first magnet piece 38 a and the second magnet piece 38 b or may bestructured of one magnet piece which is magnetized so that two differentmagnetic poles are arranged in the optical axis direction.

In the embodiment described above, the plate spring 10 is directly fixedto the magnet fixing member 14. However, the present invention is notlimited to this embodiment. For example, the plate spring 10 may befixed to the magnet fixing member 14 through a certain member. In thiscase, it may be structured that an upper face of the corner part 14 aand an upper face of the straight side part 14 b are disposed on thesame plane and that an under face of the corner part 14 a and an underface of the straight side part 14 b are disposed on the same plane.Further, in the embodiment described above, the plate spring 11 isdirectly fixed to the magnet fixing member 15 but the plate spring 11may be fixed to the magnet fixing member 15 through a certain member.

In the embodiment described above, the photographing optical device 1 isformed in a substantially square shape when viewed in the optical axisdirection. However, the photographing optical device 1 may be formed ina substantially rectangular shape when viewed in the optical axisdirection. Further, the photographing optical device 1 may be formed inanother polygonal shape when viewed in the optical axis direction or maybe formed in a circular shape or an elliptic shape when viewed in theoptical axis direction.

While the description above refers to particular embodiments of thepresent invention, it will be understood that many modifications may bemade without departing from the spirit thereof. The accompanying claimsare intended to cover such modifications as would fall within the truescope and spirit of the present invention.

The presently disclosed embodiments are therefore to be considered inall respects as illustrative and not restrictive, the scope of theinvention being indicated by the appended claims, rather than theforegoing description, and all changes which come within the meaning andrange of equivalency of the claims are therefore intended to be embracedtherein.

1. A photographing optical device comprising: a movable modulecomprising: a movable body which holds a lens and is movable in anoptical axis direction of the lens; and a holding body structured tomovably hold the movable body in the optical axis direction; a supportbody structured to swingably hold the movable module; a lens drive coilwhich is attached to the movable body; a shake correction coil which isattached to the support body; a plurality of drive magnets having afirst opposed face which faces the lens drive coil and a second opposedface which faces the shake correction coil, the drive magnets beingattached to the holding body; and a first plate spring which connectsthe movable module with the support body on the anti-object side; andwherein when one side in the optical axis direction is an object sideand the other side in the optical axis direction is an anti-object side,the holding body comprises: a first magnet fixing member to which endfaces on the object side of the plurality of the drive magnets arefixed; and a second magnet fixing member to which end faces on theanti-object side of the plurality of the drive magnets are fixed;wherein the first magnet fixing member and the second magnet fixingmember are formed in a frame shape; wherein the movable body is disposedon inner peripheral sides of the first magnet fixing member and thesecond magnet fixing member formed in the frame shape; wherein thesupport body comprises a case body structuring an outer peripheral faceof the support body; wherein an object side end of the case body isformed with a facing part which faces a part of an end face on theobject side of the movable body in the optical axis direction so as tobe capable of abutting with the part of the end face on the object sideof the movable body; wherein the second magnet fixing member is formedso as to protrude to an outer peripheral side relative to the drivemagnets, an outer peripheral surface of the second magnet fixing memberfaces the support body, and thereby a moving range of the movable modulein a direction perpendicular to the optical axis direction isrestricted, wherein the second magnet fixing member is structured torestrict the moving range by abutting the shake correction coil.
 2. Thephotographing optical device according to claim 1, further comprisingsecond plate springs structured to connect the movable body with theholding body on both end sides of the movable body in the optical axisdirection, wherein the first magnet fixing member and the second magnetfixing member are formed in a substantially quadrangular frame shapewhen viewed in the optical axis direction, wherein an outer peripheralface of the movable body is formed in a substantially octagonal shapewhen viewed in the optical axis direction, wherein the second platespring comprises: a movable body fixed part which is fixed to themovable body; a holding body fixed part which is fixed to the firstmagnet fixing member or the second magnet fixing member; and springparts which are disposed between four corner portions of the firstmagnet fixing member or the second magnet fixing member and the movablebody and are structured to connect the movable body fixed part with theholding body fixed part.
 3. The photographing optical device accordingto claim 2, wherein the first magnet fixing member is provided with fourcorner parts in a substantially “L”-shape respectively structuring thefour corner portions of the first magnet fixing member whose shape whenviewed in the optical axis direction is a substantially quadrangularframe shape and four straight side parts in a straight shape connectingthe corner parts, the holding body fixed part of the second plate springconnecting the movable body with the holding body on the object side ofthe movable body is fixed to a face on the anti-object side of thecorner part, and a face on the object side of the corner part isdisposed on the anti-object side relative to a face on the object sideof the straight side part, and a face on the anti-object side of thecorner part is disposed on the anti-object side relative to a face onthe anti-object side of the straight side part.
 4. The photographingoptical device according to claim 1, further comprising second platesprings structured to connect the movable body with the holding body onboth end sides of the movable body in the optical axis direction,wherein the first magnet fixing member is formed in a substantiallyquadrangular frame shape when viewed in the optical axis direction,wherein the second plate spring which connects the movable body with theholding body on the object side of the movable body comprises: a movablebody fixed part which is fixed to the movable body; holding body fixedparts which are fixed to the first magnet fixing member; and springparts which connect the movable body fixed part with the holding bodyfixed parts, and wherein the holding body fixed parts of the secondplate spring which connect the movable body with the holding body on theobject side of the movable body are fixed to faces on the object side offour corner portions of the first magnet fixing member whose shape whenviewed in the optical axis direction is a substantially quadrangularframe shape.
 5. The photographing optical device according to claim 1,wherein the movable body comprises: a sleeve whose outer peripheral faceis wound around and fixed with the lens drive coil; and a stopper whichis fixed on the object side of the sleeve, the stopper is formed so asto enlarge to an outer peripheral side relative to the outer peripheralface of the sleeve, and at least a part of the stopper faces the facingpart in the optical axis direction so as to be capable of abutting withthe facing part.
 6. The photographing optical device according to claim5, wherein the stopper is formed in a ring shape whose outer peripheralend is formed in a circular shape.
 7. The photographing optical deviceaccording to claim 5, further comprising second plate springs structuredto connect the movable body with the holding body on both end sides ofthe movable body in the optical axis direction, wherein the second platespring which connects the movable body with the holding body on theobject side of the movable body comprises: a movable body fixed partwhich is fixed to the movable body; holding body fixed parts which arefixed to the first magnet fixing member; and spring parts which connectthe movable body fixed part with the holding body fixed parts, andwherein the movable body fixed part of the second plate spring whichconnects the movable body with the holding body on the object side ofthe movable body is fixed in a sandwiched state between a spring fixingface formed on the object side of the sleeve and the stopper in theoptical axis direction.
 8. The photographing optical device according toclaim 1, wherein an end face on the object side of the case body wherethe facing part is formed with a cut-out part for exposing a part of thefirst magnet fixing member when viewed in the optical axis direction. 9.The photographing optical device according to claim 1, wherein surfacesof the drive magnet, the first magnet fixing member and the secondmagnet fixing member are formed with a nickel plated layer containing atleast nickel, the first magnet fixing member and the drive magnet arejoined to each other by a first joining layer which is made of tin basedmetal containing at least tin and is disposed between the first magnetfixing member and the drive magnet, and the second magnet fixing memberand the drive magnet are joined to each other by a second joining layerwhich is made of tin based metal containing at least tin and is disposedbetween the second magnet fixing member and the drive magnet.
 10. Thephotographing optical device according to claim 9, further comprising afirst plate spring which connects the movable module with the supportbody on the anti-object side, wherein the case body is formed in asubstantially bottomed rectangular tube shape provided with a bottompart formed in a substantially quadrangular flat plate shape and a tubepart formed in a substantially rectangular tube shape, wherein the firstplate spring is disposed on the anti-object side with respect to thesecond magnet fixing member, and wherein the second magnet fixing memberis formed so as to protrude to an outer peripheral side relative to thedrive magnets.
 11. The photographing optical device according to claim1, wherein the case body is formed in a substantially bottomedrectangular tube shape provided with a bottom part formed in asubstantially quadrangular flat plate shape and a tube part formed in asubstantially rectangular tube shape, the bottom part is formed with athrough-hole, and the facing part is formed at an edge of thethrough-hole so as to protrude to an inner side in a radial direction ofthe lens.
 12. The photographing optical device according to claim 2,wherein the case body is formed in a substantially bottomed rectangulartube shape provided with a bottom part formed in a substantiallyquadrangular flat plate shape and a tube part formed in a substantiallyrectangular tube shape, and wherein the first plate spring is disposedon the anti-object side with respect to the second magnet fixing member.13. The photographing optical device according to claim 8, wherein thecase body is formed in a substantially bottomed rectangular tube shapeprovided with a bottom part formed in a substantially quadrangular flatplate shape and a tube part formed in a substantially rectangular tubeshape, the bottom part is formed with a through-hole, a plurality of thefacing parts is formed at an edge of the through-hole so as to protrudeto an inner side in a radial direction of the lens, and the cut-out partis formed between the facing parts in a circumferential direction of thelens.
 14. The photographing optical device according to claim 13,further comprising a first plate spring which connects the movablemodule with the support body on the anti-object side, wherein the secondmagnet fixing member is formed so as to protrude to an outer peripheralside relative to the drive magnets.